Flow control system



Fell 3, 1953 s. L.' ADELsoN 2,627,280

FLOW CONTROL SYSTEM IN VEN TOR.

Feb. 3, 1953 s. L. ADELsoN` FLow CONTROL SYSTEM 5 sheets-sheet 2 Filed April 21. 1949 Jg y 31 IN1/Ewan 'me, (Medion,

Feb. 3, 1953 s. L. ADELsoN FLOW CONTROL SYSTEM Filed April 21, 1949 3 Sheets-Sheet 3 Patented Feb. 3, 19,53

UNITED STATES PATENT OFFICE FLOW CONTROL SYSTEM `Samuel L. Adelson, Chicago, Ill., assigner to Inflco Incorporated, Chicago, Ill., acorporation of Delaware Application AprilZl. 1949, Serial N0. A88,"8'78 A specific object of this invention is to provide a system for controlling the rate of ow of a uid in accordance with a predetermined p-rogram.

A further object is to provide a flow control system wherein the ilo-w programmer may be remotely locatedfrom the controller.

A further object ofthe invention is to provide a simple means in a flow control system whereby the ow rate is indicated at any instant, and whereby indication is immediately given of any departure of the actual ow rate from the then programmed ow rate.

These and other objects will become apparent from a consideration of the description and claims which follow.

The range of control that can be covered by my new system with high accuracy is very wide. It is possible with my` system to control program ow rates at 0.5 per cent of the maximum flow rate with an error'within 5 percentof `absolute flow, or at 1.0 per cent of the maximum flow rate with an error within 2.5 per cent of absolute ow, with corresponding accuracies at other rates, the accuracies improving as the overall range `of now control decreases.

My new system of flow control comprises a controller located at or near the place of fluid discharge, a programmer, which maybe at any suitable location remote `from the controller, and suitable electrical connections between the programmer and the controller. The` main elements of my controller include a tank, a partition across the tank separating therein an inlet` chamber into whicha uid inlet line discharges, from an outlet chamber from which a fluid discharge line leads, a plurality of orices of suitable diameters in the partition, means for selectively opening and closing one or more of the orices, and means for maintaining a constant predetermined pressure difference between the `upstream andthe downstream sides of the orices. Any` suitable means capable of maintaining a predetermined pressure drop across the orices may be used. For example, these means may include one or more inlet valves between the source of inlet 1 supply andthe tank, and

means for controlling the degree of opening `or closing of theinlet valve or valves.

The inlet valve is of a type wherein the degree of opening of the valve is determined by the pressure admitted to a diaphragm chamber to move a diaphragm and its. associated valve mechanism. The greater this pressure the` greater will be thevalve opening and viceversa. Valves of this type are well knownn the art.

The programmer is adapted to. control the means for selectively openingand closing one or more of the orifices in correspondence with the programmed rate of iiow, `andis also adaptedto select the controllable inlet valveor valves to loe` used for different programmed rates. My preferred programmer comprises a roll of suitable an electrical switch or switches, corresponding.

to the location of the corresponding perforations. Closing of these switches causes opening` of the corresponding orices. At each succeeding interval of forward movement of the roll, a new group `of perforations is brought intoA alignment position. If in the new group one or more per-l forations have a similar location as perforations of the preceding group, switches will remain closed, `and consequently the corresponding orifices will remain open.. If the new group does not include any perforations corresponding to perforations in` the previous group, the switches that were closed by the previous group will open and the corresponding oriices will close. In this manner any number of orices can selectively be opened and closed or remain open in accordance with the perforations in the roll as determined by a desired rate of low program. Where a program involves wide variations of the flow rate, I prefer to provide several inlet valves, preferably. of diierent capacity range, and to selectively use one or `more of these inlet valves for different ranges of `flow.`

In such case additional perforations are provided in each group of perforations on the moving roll, these additional perforations 'being aligned to control solenoid operated valves associated with the operating means for `the inlet valves.

My invention will be understoodmore fully by` the cor-responding` reference to the drawings which form a part hereof, and wherein similar elements in the various iigures have been designated by like reference characters.

Figure 1 is a vertical cross sectional View of the controller of my system;

Figure 2 is a sectional view taken along the line 2-2 of Figure 1;

Figure `3 is a cross sectional diagrammatic view of a constant diierential regulator for positioning the inlet control valve.

Figure 4 is a perspective View showing diagrammatically the programmer of my system; and

Figure 5 is a wiring diagram for the control system.

The controller comprises a tank I of any suitable shape but which is shown in Figure 1 as a cylindrical tank having a bottom II and an upstanding wall I2. The bottom II may be sloped inwardly to a valved drain I3, as shown. The tank I0 may be open, when the ow to be controlled discharges under gravity, but must be closed when used for controlling the rate of flow of a gas or of liquid discharged under pressure. For purposes of exemplication and illustration the tank I0 is shown in Figure 1 as provided with a cover or lid I which may be fastened to the tank I0 by any suitable means, not shown, to provide a fluid tight seal. When using the tank for controlling a liquid, a valved vent I4 is provided to permit the discharge of gas that may be trapped under the cover I5.

The fluid arrives through an inlet conduit I6 which may discharge in the lower part of the tank' I0, as shown, and leaves the tank through an outlet IB which may lead from an upper kportion of the tank. The inlet conduit I6 is provided with a control valve Il. When the overall range of flow control is wide, I may provide a plurality of inlet control valves, which maybe used alternately or in unison, depending on the programmed rates. For example, up to an overall range of about 40 to 1, one inlet valve will be sufcient. At higher ranges, two or more valves may be used.- Such an arrangement is shown in FigureV 2, where the valve Ila is connected in parallel with valve I'I on inlet conduit VI6 by a by-pass I9, branching off conduit IB upstream of valve Il and discharging to conduit I6 downstream of valve Il. Obviously, several valves can be arranged in this manner in parallel with valve I'I.'

- A Yhorizontal partition or i6 and spaced below the outlet I8 and forms in the tank a lower inlet chamber 2| and an upper outlet chamber 22. A plurality of oriiices of suitable diameters are fixed in the dividing plate 2b and afford communication between the chambers 2I and 22. Only three orices 23, 23a and 23h are shown in Figure 1 for purposes of simplication. However, it should be understood that a greater number isusually provided and that the number used will vary with the range of flow control to be covered and the absolute accuracy required. shown, in some cases it will be desirable to use orices of identical size. sealing member of any suitable kind, such as plates 24, 24a and Zlib of Figure 1, is provided, which is adapted to seal the respective orice. The sealing plates 24, 24a,72llb are xed to rods 25, 25a, 25h which pass through stuing boxes 26,*26a, 2619. The stuiing boxes are xedly and dividing plate 20 ex-l tends across the tank substantially above the inlet While orifices of diierent size are For each orice aV 4 tightly supported by the tank cover I5 and form uid tight seals around the rods 25. When an open tank is used, the rods can be supported by a bridge or by beams spanning the tank, and in this case, obviously the stumg boxes will not be needed.

The rods 25 may be operated lto raise and lower the sealing plates 2G to open or close the orifices 23 by means of solenoids or hydraulic cylinders. In Figure 1 rods 25 and 25a which are associated with the plates for the relatively small orifices 23 and 23a are shown as connected to the plungers 4I and la of solenoids Il and lila respectively. Rod 25h which is associated with the plate for the large orice 23o is connected to the piston 5I of a hydraulic cylinder 50. In the preferred form of my controller the choice between solenoids and hydraulic cylinders is determined by the size of the associated orice. However, it should be understood, that, if desired, all rods can be operated by solenoids or by hydraulic cylinders.

When using the controller for controlling the rate of flow of a liquid I may provide a suitably perforated distribution plate 2l across the tank at an elevation intermediate the inlet I andthe partition 2li. The plate 2l serves to properly distribute the incoming liquid and eliminate or reduce its turbulence as it approaches an open orice.

A constant diierential regulator Sli is connected to the inlet chamber 2| by a high pressure line 3l and to the outlet chamber 22 by a low pressure line 32. The regulator 39 is set for a predetermined pressure differential across the orices 23 and adapted to control the inlet valve or valves to the tank I0 to maintain the predetermined differential. Devices of this kind are well known in the art and any device capable of controlling the inlet valve to maintain the diiferential across the orifices 23 constant may be used. For purposes of illustration one simple form of a pneumatically operating regulator is shown diagrammatically in Figure 3, but it will be understood that other pneumatically or hydraulically operating regulators can be used. Briefly, the regulator 3d comprises a housing 6I) of suitable shape which is divided by diaphragms 6I, 62 and 63 into an air pressure chamber 64, a low pressure chamber 65 connected to outlet chamber 22 by conduit 32, a high pressure chamber t6 connected toV inlet chamber 2l by con# duit 3l, and a spring chamber 6l. The air pressure chamber Sil is connected to a source or air under pressure, not shown, through line 33 and air inlet valve 65, and tothe inlet control valve Il through an air port 69 and a controlled air pressure line .til provided with a solenoid operated valve 35. The port 69 is also connected to valve Ila by line 3% provided with a solenoid operated valve 3l. The valves 35 and 3l have a fully open and a fully closed position which they assume when their solenoids are energized or deenergized, respectively.Y When valve 35 is in closed position, the air pressure derived from the regulator 30 is cut oi from the diaphragm chamber of inlet valve I'I, and valve I closes. Similarly, when solenoid operated valve 3l' is in closed position, the air pressure is cut oil from the diaphragm chamber of valve Ila, and valve Ila closes. Whether valve 35 or valve 3l or both valves Vare open or closed, is determined by the programmer in a manner to be described below; Diaphragms 6I and 63 have equal effective areas, while diaphragm B2 has a larger effective areathan the diaphragms 6| and S3; The three diaphragms are connected vthrough their center plates, as shown, to move in unison.

A spring lil in spring chamber ill is set to balance the predetermined diiierential between the pressures in high pressure chamber t6 and low pressure chamber et. when the .pressure differential across the orifices 23 is at the desired Value the air inlet valve 68 is throttled to such an eX- tent that the pressure drop therethrough produces in chamber es and diaphragm chamber of valve Il apressure such that the degree cfcpening of valve li and the flow therethrough are of the proper values to produce this desired differential pressure across 'orifices 23.

If the differential pressure acrossthe orifices Z3 increases, say due to an increase iii the pressure of the fluid entering control valve il and hence an increase in the flow therethrough, the diierential pressure across diaphragm S2 of regulator will begreater than the set tension value of spring 'lll and the diaphragm assembly will move in a direction to further throttle valve 658 to decrease the pressure in chamber 6?, and diaphragm casing of valve il. This will cause the inlet valve il to move to a more closedposition and to reduce the flow therethrough until the differential pressure across the orifices 23 is restored to its predeterminedvalue. The procedure is reversed upon a decrease in the diiierential pressure from its predetermined value.

Valve lla functions similarly when its solenoid operated valve 3l is open,

As shown in Figure 4, the ow programmer of my system may comprise a roll 8d of suitable material which is perforated with holes ill arranged in suitable groups and rows, the location of a perforation in a row corresponding to a definite orice 23 or to a valve on the iiow controller. The roll 823 is threaded in a mandrel i'land is moved intermittently forwardly by suitable drive means, not shown, over a bar S3 which is provided with openings 8d. The openings 3d correspond in number to the maximum number of perforations used in one row of the roll til. The openings Bil are located in such .manner along the bar 83' that each perforation 8| in a row registers with an opening til as the roll 8e moves over the bar 33. The forward movement of the roll till is controlled by a timer or the like, not shown, in such manner that the roll will stop each time a row of periorations il! registers with the openings 84 ci bar t3.

l A vacuum motor 35 of known construction is shown connected to one or the openings Se in the bar 83 by a line 3S. While only one vacuum motor 85' is shown and will be described for simpliiication, it will be understood that the number of vacuum motors to be provided corresponds to the maximum number of perorations 8| to be used in one row. A line ill leads from the vacuum motor 35 to a source of vacuum, not shown. The vacuum motor @5 is provided with an extension 88 which is movable with the top or the vacuum motor and with a stationary extension t9 as shown. The extensions es and Sli carry a pair of normally spaced contacts el and et which are suitably connected in. an electric circuit to be described below.

When a perforation 3i of the roll. fill registers with an opening es of the bar 83, air is admitted to the vacuum motor and the vacuum broken. The movable top of the motor. carrying extension 88 and` contact lll, moves upwardly and contacts SG and 9| are brought together to closey an' e'lectrieri circuit.

Figure 5 shows a Wiring diagram for my' control system. Wiring below line n n represents that inder 5|) in the diagram are those shown in Figure l Aas controlling the position of the valve plates 24, 24a and Zlib, respectively. Operation of hydraulic cylinder 5i) is controlled by-a four-Way pilot valve 5e which, in turn, is operated by a sole-'- noid 55. Solenoids 33 and 39 operate the valves 35 and 3l of Figure 1. Contacts Sil and 9| are those shown in Figure 4.

A source of electric power L1 and L2' enters the programming station while a source of power PiPz enters the flow controller station. It is ob'- vious that the source P1132 may be obtained di'- rectly from L1L2 and also that the solenoids 4|! and four-way pilot valve 55 maybe operated directed instead of through relays, but since the only power supply available may be alternating current and since the inrush current to alternating current solenoids is approximately ten times the holding current and thereby causes a large line voltage drop, it is believed to be more economical to employ relays and light transmission lines rather than the heavy transmission lines necessary to hold the voltage drop down toa permissible value. This diagram therefore is based on the use of alternating current although direct current may also be employed with or Without the use of relays.

The plunger of each of the solenoids de and den: is provided with an extension l2 or liza carrying an insulated contact bar 43 or 63a, respectively, so that when the solenoid is in the closed position the contact bar 133 or 13a bridges the contacts is and lili or lila and Alea., respectively. The piston of the cylinder till carries an insulated bar 43h which when the piston 5| has reached the upper limit of its stroke will bridge the contacts db and del).

To the line L1 or the source of power supply at the programming station are connected the contacts 9| to sid inclusive by a common header 92. Contact @il is connected to one terminal of the coil of a relay 93| by conductor ist. Contacts Qta, Stb, etc and lied are connected to one terminal of the coils of relays ldlc, lllJ, ISD and` Ita conductors Ml, M2, l and Mii respectively. The other terminals of the relay coils are connected to a common conductor 5e and thence to the ilne L2 of the source of power supply.

One terminal of each of the lamps |52, |520, and |5221 is connected to a common header |5| leading to power line Le. The other terminal of each of the lamps |52, |52a and |522) is connected to contacts 25, 45u and 135e, respectively, and to one terminal of each of suitable resistors |60, ISM and web by conductors |53, li and |55,- respectively.

The other terminals of the resistors |60, i60/c and llo are connected to contacts 44, Mc and Mb yby conductors lll), lll and |72, respectively, and also to conductors M0, lil and |42, respectively.

Relays |3| vare of the single pole 4type and relays IBil are of the double pole type. Line |43 is connected to pole |33 of relay |80 by conductor Illll and line |44 is connec-ted to pole |35 by con-i -ductor ISE. One terminal of each of the lamps accused |BI and IBIa, is connected to the common headerV |5|. The other terminal of lamp |8| is connected to the contact |81 of relay |80 by conductor |88 and the other terminal of lamp I8 Ia is connected to contact |89 of relay |80a, by conductor |90.

One terminal of solenoid 40 is connected to pole of relay I3I by conductor IOI. Contact |02 of relay I3| is connected to power supply line P2 by conductor |03. The other terminal of solenoid 40 is connected to power line P1 by conductor |04.

One terminal of solenoid 40a is connected to pole I00a of relay I3|a by conductor IOIa. Contact I02a of relay I3Ia is connected to power supply line P2 by conductor I03a. The other terminal of solenoid 40a is connected to power line P1 by conductor |04a.

One terminal of coil of solenoid 56 of four way pilot valve 55 is connected to pole I00b of relay I3Ib by conductor IIIIb, contact Ib of relay I3 Ib is connected to power supply line P2 by conductor I03b. The other terminal of the coil of solenoid 56 is connected to power line P1 by conductor I04b.

One terminal of the coil of solenoid 3B of shut off valve 35 is connected to pole ||0 of relay |30 by conductor |I3. Contact III of relay |80 is connected to power line P2 by conductor H2. The other terminal of the coil of solenoid 38 is connected to power line P1 by conductor H4.

One terminal of the coil of solenoid 39 of shut ofl` Valve 3'I is connected -to pole I|0a of relay |3011. by conductor H30.. Contact Illa. of relay llla. is connected to power line Pz by conductor |I2a. The other terminal of the coil of solenoid 33 is connected to power line P1 by conductor |I4a.

In operation, say contacts 90 and 9| of Figures'l and 5 are close-d because a perforation in the roll 80 aligned with its corresponding opening in the bar 83. Current will then ow from line L1 through contacts 9| and .90, conductor |40, coil of relay I3|, to conductor |50 back to power line L2. This will energize the coil to close a circuit from power line P2, conductor |03, contact |02, pole litt, line 50|, solenoid 40 and line |05 to power line P1. The solenoid will be energized `to raise the plate 24 oil the orifice 23 (Fig. 1) and permit passage of water at a rate corresponding to the diameter of the orifice and the set diierential head.

If the plunger 4| of solenoid 40 moves through its full stroke, or as commonly expressed, seals, then contact bar 43 on plunger extension 42 will bridge the contacts 44 and 45.

The lamp |52 will then be lighted at its full intensity, the circuit being as follows: from power line L1, through contacts 9| and 90, conductors |40 and |10, contact 44, contact bar 43, contact 45, conductor |53, lamp |52, conductor I5| to power line L2.

If, however, the plunger 4| shall not seal, or not move at all, the resistance Ict will then be in series with the lamp |52 as the contacts 44 and 45 will not be bridged. As the value of this resistor is so chosen that when it is in series with the lamp, the lamp will be dimly lighted, it will be noticed that although the program called for thisforice to open it either has not done so, or

that the plunger has not sealed and `there is danger of it burning out. Obviously, since each of the lamps |52, |53a etc. is associated with a definite orifice .whose flow rate is known, the digression from the programmed iow rate caused by failure of the orice to open can be computed.

The circuit is as follows: power line L1. contacts 9| and 90, line |40, resistor |60, line |53, lamp |52,

conductor |5I to line L2.

The action will be alike for all solenoid operated orifices and valves. With cylinder operated oriiices, if the piston does not move or make its full stroke, contacts 44D and 45h will not be bridged and the corresponding lamps will be dimly lighted.

It is obvious that while the operation has been given for one solenoid or one cylinder operated orifice, the action will be the same and occur simultaneously for each of a plurality of solenoid and cylinder operated orices which the programmed perforations on the roll may call for. and also for the solenoid operated valves 35 and 3l. Resistors for the indicating lamps I8I and IIa associated with valves 35 and 31 are not shown, .but may be provided if desirable. In each row of perforations -on roll 80 perforations controlling opening or closing of the solenoid operated valves 35 and 3l will be provided to open either or both of these valves in accordance with the number and size of the orifices to be opened by perforations in that row.

It will be seen from the above description that the flow control system of my invention is adapted to operate withY great accuracy and repetitiveness over a wide range of flow rates and with widely varying now rates. It will also be obvious to those skilled in the art that many modications of the apparatus shown for purposes of exemplication and illustration may be made without departing from the scope and spirit of the invention. Thus it will be understood that the programmer need not be in the form described and shown in Figure 4. Any device capable of selectively opening or closing one or more of the orices 23 as required by a iiow program may be used. However, when the range of now rates is Wide and the accuracy required is high, I prefer to use the new programmer described, as it is especially suited f or such requirements.

I claim:

l. In a flow control system including a controller, a programmer and electrical means for transmitting a program from the programmer to the controller, an improved controller comprising a tank, an inlet into said tank, an outlet from said tank functionally remote from said inlet, a partition in said tank intermediate said inlet and said outlet, a plurality of oririces in said partition, means adapted to maintain a predetermined pressure difference between the upstream and downstream side of said oriiices, and-means associated with said oriiices for selectively opening or closing one or more of said oririces to provide now rates in accordance with the now program set by said programmer, said last mentioned means being operated by said electrical transmitting means.

2. A ow control system including a controller, a

programmer and electrical means for transmitting a program from the programmer to the controller, said controller comprising a tank, an inlet into said tank, an outlet from said tank remote from said inlet, a partition across said tank intermediate said inlet and said outlet, a plurality of orifices in said partition, means adapted to maintain a predetermined pressure diii'erence between the upstream and downstream side of said orifices, said means including a pressure differential responsive device connected to said tank on the upstream side and on the downstream side of said orifices, a iiuid pressure operated control valve associated with said inlet, a pressure fluid connection from said pressure differential responsive device to said control valve, said pressure difierential responsive device establishing in said fluid connection a pressure which varies inversely to variations in the pressure dfference between the upstream and the downstream side of said orimeans being positioned by said electrical means.`

3. The apparatus of claim 2, including also means associated with said pressure differential responsive device adapted to balance a predetermined pressure diilerencc between the upstream side and the downstream side 0f said orifices.

4. A control system adapted to automatically control rates of fluid now in accordance with a remotely set program, said system including a programmer, a controller comprising a tank having an inlet and an outlet functionally remote from said inlet, a partition interposed between said inlet and said outlet, orices in said partition, a sealing member associated with each orice, and a solenoid operatively connected with each sealing member and adapted to move said member to open and close its orice, and a power circuit from said programmer to each solenoid, a switch in each power circuit, said switches being positioned by said programmer in accordance with the rate of ow program, a control valve on said inlet, and regulating means connected to said control valve for setting said control valve to maintain a predetermined differential between the upstream and downstream side of said orifices.

5. A control system adapted to control the rate of flow of a uid in accordance with a predetermined program, comprising a tank, an inlet into said tank, an outlet from said tank functionally remote from said inlet, a partition in said tank intermediate said inlet and said outlet, a plurality of orifices of dierent size in said partition, means including an inlet control valve and a pressure differential sensitive device adapted to maintain a predetermined pressure drop across said orices, a sealing member for each of said orices, electrical means operable to selectively hold one or more sealing members in sealing position and to move them into, and hold them in, non-sealing position relative to said oriiices, said electrical means being connected in a programmed power circuit.

6. A fluid flow control system comprising a tank having an inlet and an outlet functionally remote from said inlet, a partition interposed in the line of flow from said inlet to said outlet, a plurality of oriiices in said partition7 a pressure differential responsive device, said pressure differential responsive device being connected to said tank upstream of said oriiices and downstream thereof, an inlet valve associated with said inlet and adapted to be positioned by said pressure diiierential responsive device, biasing means associated with said pressure differential responsive device and adapted to balance a predetermined pressure differential acting on said device, a sealing plate for each of said orifices, rods ailixed to said plates and extending to outside said tank, and means for selectively moving one or more of 10 said rods to hold their associated sealing plates in sealing relation with the orices 0r to move them into, and hold them in, non-sealing position,y electrical means controlling the operation of said last mentioned means, and a programmer operating said electrical means in accordance with a predetermined flow program.

7. The apparatus of claim 6, wherein at least one of said rods is moved by hydraulic means.

8. The apparatus of claim 6 wherein at least one of said rods is moved by electrical means.4

9. A fluid dow, control system comprising a tank having a fluid inlet and a uid outlet functionally remote from said inlet, a partition interposed in the` line of ilcwfrom said ,inletto said ou.tlet,"a plurality oifcrces through said partitionmeans associated with said tank and adapted tomairfltain a predetermined-pressure diierence'between the upstream side andthe downstream side of said orices, and means for automatically opening and closing selected orices in accordance with programmed rates of flow, said means including a sealing member for each of said oriiices, solenoids operatively connected with said sealing members, a roll of flexible material perforated in accordance with the flow program, each perforation in a row of perforations corresponding to a definite orifice in the partition, a slotted bar, said roll being adapted for intermittent forward movement over said bar and alignment of successive rows of orifices with the slots of said bar, an electric switch for each of said orices, means operative to close the switch of an orifice when a perforation corresponding to such orice is aligned with a slot of said bar, and a power circuit closed by closing of the switch and including the solenoid of the respective orice sealing member.

10. An apparatus according to claim 9 wherein said means for maintaining a predetermined pressure difference includes a pressure differential sensitive member connected to said tank upstream and downstream of said orices, plural inlet control valves associated with said inlet, a pressure fluid connection between said pressure differential sensitive member and each of said inlet control valves, and a solenoid operated valve on each of said pressure fluid connections, and wherein means are provided for selectively opening either one or more of said solenoid operated valves, said means including additional perforations on said roll corresponding to said solenoid operated valves, an electric switch for each solenoid operated valve adapted to close when a perforation corresponding to the respective valve registers with a slot in said bar, and a power circuit closed by closing of the valve switch, the solenoid of the respective valve being connected in said power circuit.

l1. Apparatus according to claim 9, including also a signal means for each orifice, said signal means being connected to said power circuit and operative to indicate opening of said orifices.

l2. Apparatus according to claim 11 wherein said signal means are so connected to said power circuit as to give one signal when an orice opens according to program, and a different signal when an orifice fails to open according to program.

13. A fluid flow controller adapted to control rates of fluid now in accordance with a flow program, comprising a tank, an inlet into said tank, an outlet from said tank functionally remate from said inlet, a partition in said tank interposed between said inlet and said outlet, orices in said partition, sealing members for said orifices, means 11 Y 12 for selectively operating said sealing members to REFERENCES CITED open and close Selected orifices according to a The following references are of record-in the flow program, means for maintaining a constant me of this partent. predetermined pressure difference between the upstream side and the downstream side of said 5 UNITED STATES PATENTS orifices, said last mentioned means comprising a Number Name Date pressure differential sensitive device set for the 2,157,707 Keel May 9, 1939 predetermined pressure difference, a plurality Of 2,343,375 Herman Mar. 7, 1944 inlet control valves connected in parallel to said 2,484,916 Tucker Oct. 18, 1949 inlet, pressure 'uid conduits connecting said 10 FOREIGN PATENTS pressure differential sensitive device to said inlet valves, valves in said conduits, and means to se- Number COUNTY Date lectively open one or more of said valves in ac- 791,223 France 0f 1935 cordance with said program, a programmer, and electrical means operated by said programmer 15 and operating said sealing members and said means for selectively opening one or more valves.

SAMUEL L. ADELSON. 

